KR20110041132A - Radiation irradiator with the alignment reference plane - Google Patents

Abstract

PURPOSE: A radiation irradiator with an alignment reference surface is provided to conveniently and precisely perform alignment between the radiation irradiator and a rail system using the alignment reference surface placed on the frontal surface of the radiation irradiator without a film work. CONSTITUTION: An alignment reference surface(12) is flat on the frontal surface of a basic radiation object(11). Data for measuring the slope which makes an alignment reference surface and a central axis(15) is used as a parameter for an alignment work. A radiation traveling route(16) and a loader mounting groove(17) penetrate the alignment reference surface on the central axis and makes a concentric axis.

Description

Radiation irradiator with the alignment reference plane

The present invention relates to a radiation irradiator for irradiating radiation to a radiation dosimeter to calibrate a radiation dosimeter, and more particularly, to a technology for easily and accurately performing alignment between the radiation irradiator and a rail system on which a mobile calibration table is seated. It is about.

In general, the radiation dosimeter for measuring the dose rate of the radiation is periodically calibrated to ensure the accuracy and reliability of the performance, and in order to calibrate the radiation dosimeter, a radiation irradiator that artificially irradiates the radiation dosimeter need.

Such a radiation irradiator freely adjusts its position while being mounted on the top of a separate reference point adjusting device so as to accurately set a reference point of a radiation source installed therein, and a rail system is installed on the front bottom surface of the irradiator. At the top of the system is a mobile calibration table on which the radiation dose meter is to be calibrated, allowing the irradiator to irradiate the radiation meter.

Here, the irradiator and the rail system are individually manufactured and then constructed as a single calibration system through on-site construction. In this process, the radiation source and the rail system installed in the irradiator are necessarily aligned to make precise parallelism with each other. do.

That is, the correct alignment between the irradiator and the rail system is possible only when the correct alignment between the irradiator and the rail system is possible so that the radiation can be accurately irradiated on the radiation meter installed on the movable calibration station moving along the rail system.

Conventionally, there is no way to check the alignment between the radiation irradiator and the rail system. However, as a method for confirming this, the photosensitive film is installed on the movable calibration stand, and the radiation is irradiated to the photosensitive film. By developing this, it is possible to confirm the irradiation position of the radiation, and this film work is repeated several times while changing the position of the radiation irradiator until the radiation is irradiated to the center of the photosensitive film.

However, the conventional method not only takes a lot of time and labor for setting, developing, and irradiating the film repeatedly, but also makes the work very difficult and raises the cost, and above all, the location of the radiation irradiated on the photosensitive film. By visually checking and adjusting the position of the irradiator, there is a problem that the accuracy of alignment is lowered.

The present invention is to actively solve the problem requiring improvement from the alignment operation according to the prior art, the alignment operation between the irradiator and the rail system using the alignment reference plane provided on the front of the irradiator without the film work To be more precise and simple to perform as a problem of the invention.

The present invention is a technique for forming an alignment reference plane on the front surface of the radiation irradiator as a means for solving the above problems, by measuring the inclination between the alignment reference plane and the center axis of the source where the radiation source is located and using it as a parameter of the alignment operation It is characterized by seeking.

In addition, the present invention is characterized in that a technique for installing a radiation progress path and a source loader mounting groove forming a concentric axis passing through the alignment reference plane on the line center axis.

In addition, the present invention is characterized in that a technique for locating a mobile radiation source to form a concentric axis while forming a radiation traveling path passing through the alignment reference plane on the line center axis.

In addition, the present invention is characterized in that the technology for installing a collimator mounting groove in front of the progress path.

According to the present invention, the alignment reference plane installed on the front side of the irradiator provides an effect of primarily performing alignment between the irradiator and the rail system while measuring the degree of tilting the tilt system with the rail system using an auto collimator or the like.

In addition, by applying a parameter measuring the inclination between the alignment reference plane and the center axis of the source by secondly correcting the position of the radiation irradiator provides an effect that can quickly and easily and very precisely align the radiation source and the rail system do.

It will be described a preferred embodiment for implementing the solution of the problem to be solved by the present invention in more detail.

Firstly, the present invention includes the radiation irradiator 10 of the first embodiment in which the radiation source is fixedly installed as shown in FIGS. 1 to 5, and the radiation irradiator of the second embodiment in which the radiation source is movable as shown in FIGS. It is assumed that they are all applicable to (10a).

The present invention is a flat on the front surface of the irradiation main body 11 so that the radiation irradiator 10 (10a) can easily measure the degree of tilt (deviation) from the rail system through an optical method or a mechanical method using an auto collimator or the like. An alignment reference plane 12 is formed.

Therefore, when the auto collimator is installed on the movable calibration table and the beam is irradiated to the alignment reference plane 12, the beam reflected from the alignment reference plane 12 does not coincide with the rail system so as to be distorted. ), And adjusting the position of the radiation irradiator 10 (10a) in consideration of the inclination, it is possible to easily perform the alignment between the radiation irradiator 10 (10a) and the rail system primarily.

Here, the present invention sets the source center axis 15 on which the radiation source is located based on the alignment reference plane 12, but accurately measures the inclination between the alignment reference plane 12 and the source center axis 15 in advance. The measured data is used as a parameter for sorting.

The reason for this is that even if the accuracy is high in the process of fabricating the irradiation primitive 11, the inclination between the alignment reference plane 12 and the source center axis 15 is determined in advance as the error is different from the design matter. This is because correcting the position of the irradiator 10 (10a) by applying this as a parameter can be more precise and perfect alignment.

In addition, a radiation propagation path 16 is formed on the axis line of the source central axis 15 applied to the radiation irradiator 10 of the first embodiment so that radiation can be irradiated through the alignment reference plane 12. At the rear of 16), the source loader mounting groove 17 for fixedly mounting a separate source loader loaded with the radiation source is installed to be concentric with the source central axis 15 so that the central axis of the radiation source is always the source central axis 15. It can be concentric with.

In addition, in front of the source loader mounting groove 17 is further formed a shutter movement path 18 to which the shielding shutter for selectively opening and closing the radiation path 16 is movable.

As shown in FIGS. 3 to 5, the inclination for use as a parameter in the alignment operation is a numerical value of the inclination between the X-axis direction horizontal plane of the alignment reference plane 12 and the source center axis 15, and the alignment reference plane 12. It is composed of the numerical value of the inclination of the vertical plane in the Y axis direction and the central axis of the source (15).

At this time, the inclination between the X-axis horizontal plane and the source center axis 15 of the alignment reference plane 12 and the inclination between the vertical axis of the Y axis direction and the source axis 15 may vary in various ways. In this case, only by performing the primary alignment between the alignment reference plane 12 and the rail system, the ship's central axis 15 can be more easily aligned by precisely and automatically aligned parallel to the rail system.

On the other hand, the radiation progress path 16 is formed on the axis line of the source central axis 15 applied to the radiation irradiator 10a of the second embodiment of the present invention through the alignment reference plane 12 as shown in FIG. A source loader movement path 19 is formed behind the radiation progress path 16, and the radiation source moving along the source loader movement path 19 is selectively positioned to form a concentric axis with the source central axis 15 so as to be second. The central axis of the radiation source applied to the radiation irradiator 10a of the embodiment can always be concentric with the source central axis 15.

In addition, the radiation irradiator 10 or 10a may be additionally installed such that the collimator mounting groove 13 for mounting the collimator in front of the radiation progress path 16 may be coaxial with the source central axis 15. Will be.

According to the present invention having such a configuration, when the optical method is used in the alignment operation, when the beam is irradiated to the alignment reference plane 12 using an auto collimator, the alignment reference plane 12 is railed through the beam reflected from the alignment reference plane 12. You will be able to measure the skewness with the system.

Thus, by adjusting the position of the radiation irradiator 10 (10a) by the measured slope, the alignment reference plane 12 and the rail system can achieve an accurate alignment primarily.

Next, a more precise alignment can be performed by correcting the position of the radiation irradiator 10 (10a) by a parameter measuring the inclination between the alignment reference plane 12 and the source center axis 15 where the radiation source is located. .

1 is a perspective view of a radiation irradiator of a first embodiment to which the present invention is applied;

Figure 2 is a longitudinal sectional view showing the internal structure of the irradiator of the first embodiment of the present invention;

3 is a front view of a radiation irradiator of a first embodiment of the present invention;

Figure 4 is a partially cutaway longitudinal cross-sectional view showing the inclination of the vertical axis in the Y axis direction of the alignment reference plane of the present invention

5 is a partially cut-away plan view showing the inclination of the horizontal axis in the X axis direction of the alignment reference plane of the present invention and the center axis

6 is a perspective view of a radiation irradiator of a second embodiment of the present invention;

7 is a partially cut-away longitudinal sectional view showing the internal structure of a radiation irradiator of a second embodiment of the present invention;

8 is a front view of the irradiator of the second embodiment of the present invention;

DESCRIPTION OF THE REFERENCE NUMERALS

10, 10a: irradiator 12: alignment reference plane

13: Collimator mounting groove 15: Sailor center axis

16: Radiation path 17: Source loader groove

Claims (7)

Forming a flat alignment reference plane 12 on the front surface of the irradiation main body 11, and using the data measured the slope formed between the alignment reference plane 12 and the source center axis 15 where the radiation source is located as a parameter for the alignment operation A radiation irradiator provided with an alignment reference plane. The method of claim 1, A radiation irradiator provided with an alignment reference plane, characterized in that the radiation progress path 16 and the source loader mounting groove 17 penetrating the alignment reference plane 12 on the axis line of the source center axis 15 to form a concentric axis. 3. The method of claim 2, A radiation irradiator provided with an alignment reference plane, characterized in that the front of the source loader mounting groove (17) is further formed with a shutter movement path (18) in which the shielding shutter is movable. The method of claim 1, The radiation traveling path 16 penetrating the alignment reference plane 12 is installed on the axis line of the source central axis 15, and moves along the source loader moving path 19 formed behind the radiation traveling path 16. A movable radiation source is provided with an alignment reference plane, characterized in that located on the axis of the central axis of the source (15) concentric axis. The method of claim 1, The inclination is formed by the inclination between the X axis direction horizontal plane of the alignment reference plane 12 and the source center axis 15, and the inclination between the Y axis direction vertical plane of the alignment reference plane 12 and the source center axis 15. A radiation irradiator provided with an alignment reference plane. The method of claim 5, The inclination between the X-axis horizontal plane and the source center axis 15 of the alignment reference plane 12 and the inclination between the Y-axis vertical plane and the source center axis 15 are formed at right angles. . The method according to claim 2 or 4, A radiation irradiator provided with an alignment reference plane, characterized in that the front of the radiation progress path (16) is further provided with a collimator mounting groove (13) forming a concentric axis with the source central axis (15).

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